JP5577298B2 - Solar module mounting bracket - Google Patents

Description

  The present invention relates to a solar module mounting bracket for fixing panel-like solar modules (solar cell modules and / or heat collecting modules) arranged on a roof.

Conventionally, when installing a panel-like solar module such as a solar cell module or a heat collection module on the roof, an appropriate support bracket is fixed on the roof, and the solar module is positioned by this, and the press attached to the support bracket The solar module is fixed with metal fittings.
In addition, a heat insulating material layer is also formed below the solar module by laying a heat insulating material on the roof before attaching the solar module.

  Patent Document 1 discloses that a heat insulating roof panel in which a heat insulating material is sandwiched between an upper metal plate and a lower metal plate, a recess is formed on the upper surface of the upper metal plate, and a solar system device (solar module) is provided in the recess. It has been proposed to install and use solar insulated roof panels. In this case, when the roof is formed, the solar heat insulating roof panel is fixed on the support member constituting the frame of the roof.

Japanese Patent Application Laid-Open No. 10-219949

  However, in the conventional solar module mounting structure, the solar module mounting and the heat insulating material mounting cannot be performed efficiently on site, and there is room for improvement in terms of workability.

  Moreover, if it is set as the structure which integrates a solar module and a heat insulating material integrally in a roof material like patent document 1, it will be difficult to attach to an existing building (existing roof), it will lack versatility, and construction cost will increase. Become.

  In addition, when installing the solar module, not only workability but also sufficient airtightness and waterproofness are required, and further, versatility that can cope with the difference in the roof shape of the existing building is required.

  In view of such a situation, the present invention is intended to improve workability on the premise of on-site construction, while improving airtightness and waterproofing, and improving versatility to cope with differences in roof shape, etc. It is an object to provide a module mounting bracket.

  In order to solve the above problems, a solar module mounting bracket according to the present invention is fixed on a roof and extends in a roof inclination direction between solar modules adjacent in a lateral direction orthogonal to the roof inclination direction. A first metal fitting and a second metal fitting fixed on the first metal fitting and extending in the same direction as the first metal fitting are configured.

The second metal fitting includes an upper surface portion located on the first metal fitting, a pair of side surface portions extending downward from the upper surface portion, and a pair of lower surface portions extending outward from the lower ends of the side surface portions. And make a hat-shaped cross section.
The lower surface portion constitutes a placement portion of an edge portion of a heat insulating material disposed below the solar module, and the upper surface portion has both widthwise end portions constituting the placement portion of the solar module frame and its width. A rail groove extending in the extending direction of the second metal fitting is provided at the central portion in the direction.
The rail groove forms a bolt engaging portion that engages with the head portion of the mounting bolt with the thread portion facing upward, and also forms a drainage passage portion that guides water in the inclination direction of the roof.
And the said thread part of the said attachment bolt makes the attachment part of the pressing metal metal which fixes the flame | frame of a solar module.

According to the present invention, by setting the heat insulating material on the lower surface portion of the second metal fitting and then setting the solar module on the upper surface portion, these can be set efficiently, and the workability is excellent.
In addition, rainwater can enter the space surrounded by the upper surface of the second metal fitting and the left and right solar module frames, but the intruded water enters the rail groove and is discharged according to the inclination of the rainwater. Intrusion is prevented and sufficient waterproofness can be exhibited. At the same time, the airtightness of the space between the solar module and the heat insulating material can be secured.
In addition, due to the difference in the roof shape, etc., it can be handled even if the interval between the frames on the second metal fitting is different, and versatility is high.

The top view of the solar system which shows one Embodiment of this invention Side view of solar system Front sectional view showing how the solar module is attached to the folded roof 3 is an enlarged view of the main part of FIG. Front sectional view showing how the solar module is mounted on another folded roof Enlarged view of the main part of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a plan view of a solar system (module arrangement) showing an embodiment of the present invention, and FIG. 2 is a side view of the solar system.

  The solar system is configured by arranging vertically (for example, 1476 x 984 mm) solar modules 1 vertically and horizontally in a matrix form (4 x 6 in the present embodiment) on the roof. -A mounting bracket 10 is interposed between the solar modules 1 and 1 that are adjacent to each other in the lateral direction perpendicular to the underwater side.

  The solar module 1 includes a solar cell module 1A and a heat collecting module 1B. In this embodiment, the vertical 3 × horizontal 6 sheets on the water side are the solar cell module 1A, and the vertical 1 × horizontal 6 sheets on the water side. Is the heat collecting module 1B.

  The solar cell module 1 </ b> A includes a rectangular frame 2 made of metal (for example, aluminum) and a PV panel 3 fitted in the upper part of the frame 2. The PV panel 3 is obtained by mounting solar cells in a matrix on transparent tempered glass (specifically, between two layers of glass plates), and generates power by receiving sunlight.

  The heat collection module 1 </ b> B includes a rectangular frame 2 made of metal (for example, aluminum) and a heat collection panel 4 fitted in the upper part of the frame 2. The heat collecting panel 4 is made of only a glass plate without a solar battery cell, and can effectively heat the internal air by receiving sunlight.

  Note that the solar cell module 1A also has a certain heat collecting effect. In this embodiment, three solar cells are obtained by flowing air from the water side to the water side in the lower space of the solar module 1. The temperature of the air is gradually raised by the module 1A, and finally, the temperature is further raised by the heat collecting module 1B so that the heated air can be taken out.

  The mounting bracket 10 fixes the panel-like solar modules 1 arranged on the roof, and is between the solar modules 1 and 1 adjacent to each other in the lateral direction perpendicular to the inclination direction of the roof (water-side-water-side). , And the appropriate position (X portion in the drawing) in the extending direction becomes the fixing portion of the frame 2 of the solar module 1.

The mounting bracket 10 and a mounting structure using the mounting bracket 10 will be described with reference to FIGS.
FIG. 3 is a front sectional view showing a solar module mounting mode on a folded plate roof (for example, 66 folded plate roof), and FIG. 4 is an enlarged view of a main part of FIG.

  The 66 folded plate roof in this embodiment has a height h1 of the mountain height of 66 mm and a pitch p1 of the mountain height of 350 mm. When the horizontal size w of the solar module 1 (frame 2) is 984 mm, the mounting bracket 10 is provided on every other mountain height, and the frames 2 and 2 of the solar modules 1 and 1 adjacent in the horizontal direction are fixed. In this case, the interval s1 between the frames 2 and 2 is p1 × 3-w, which is 66 mm.

  The mounting bracket 10 is fixed on the roof RF, in particular, on the peak portion of the folded plate roof RF, and fixed on the first bracket 11 and the first bracket 11 extending in the extending direction of the peak portion, And a second metal fitting 12 extending in the same direction as the first metal fitting 11.

  The first metal fitting 11 is a lip groove steel (C-shaped steel), and is mounted on the peak part of the folded plate roof RF with the open side of the groove facing upward, and is fixed using a sword tip bolt SB. . In addition, a hole for passing the sword tip bolt SB is made in the direction without the groove of the first metal fitting 11.

  The second metal fitting 12 extends from the upper surface portion 13 located on the first metal fitting 11, a pair of side surface portions 14, 14 extending downward from the upper surface portion 13, and the lower ends of the side surface portions 14, 14 to the outside. A hat-shaped cross section is formed including the pair of lower surface portions 15 and 15. More specifically, both end edges of the upper surface portion 13 protrude outward from the side surface portions 14, 14, and have a so-called “π” -shaped cross section. In addition, although the 2nd metal fitting 12 is good to form by extrusion molding, such as aluminum, you may form integrally from several members by welding.

  The first metal member 11 and the second metal member 12 are fixed to the side surfaces 14 and 14 of the second metal member 12 on both side surfaces of the first metal member 11 and fixed with screws 16.

Here, the lower surface portion 15 of the second metal fitting 12 serves as a mounting portion for the edge of the heat insulating material HI disposed below the solar module 1. As the heat insulating material HI, for example, a material in which both surfaces of a foam material such as phenol foam having a thickness of about 30 mm are coated with a surface material such as a polyester nonwoven fabric is preferably used.
And the heat insulating material HI is pressed down by setting a heat insulating material pressing (spacer) HM between the edge upper surface of the heat insulating material HI and the lower surface of the upper surface portion 13 and screwing it.

  That is, the height of the side surface portion 14 of the second metal fitting 12 is made higher than the thickness of the heat insulating material HI placed on the lower surface portion 15, and the heat insulating material presser (spacer) HM is equivalent to the heat insulating material HI layer. An air layer (wiring space) of at least about 10 mm is formed above, that is, between the solar module 1 (frame 2) and the heat insulating material HI.

The upper surface portion 13 of the second metal fitting 12 has both ends in the width direction serving as mounting portions for the frames 2 and 2 of the solar modules 1 and 1 and has a rail groove 17 in the center portion in the width direction.
The rail groove 17 forms a bolt engaging portion (17a) that engages with the head of the mounting bolt 21 with the thread portion facing upward, and also forms a draining passage portion (17b) that guides water in the inclination direction of the roof. To do.

  More specifically, the rail groove 17 is provided on the lower side of the first rail groove 17a that forms the bolt engaging portion and the first rail groove 17a, and extends in the same direction to form the draining passage portion. The second rail groove 17b communicates with the bottom of the first rail groove 17a.

Next, fixing of the frame 2 of the solar module 1 using the mounting bolt 21 will be described.
A side portion of the frame 2 of the solar module 1 is recessed inwardly (recessed portion 2a), and an L-shaped pressing portion 2b is formed to protrude at the lowermost portion of the frame 2.

  The threaded portion on the front end side of the mounting bolt 21 is inserted through the central hole of the downward U-shaped presser fitting 22, and the both downward ends of the presser fitting 22 are inserted into the recess 2a so as to be opposed to the presser 2b. is there. Therefore, the frame 2 of the solar module 1 can be pressed and fixed by the presser fitting 22 by screwing and tightening the nut 23 to the bolt 21 from above the presser fixture 22. The presser fitting 22 is formed with ribs that rise upward for reinforcement.

  Further, an upward U-shaped retainer 24 is fixed to the mounting bolt 21 with a nut 23 together with the presser fitting 22. The retainer 24 is for attaching a drain cover 25 that closes the opening between the frames 2 and 2 of the solar modules 1 and 1 that are adjacent in the lateral direction.

  The drainage cover 25 is a thin plate, is provided so as to straddle the top surfaces of the frames 2 and 2 of the solar modules 1 and 1 adjacent in the lateral direction, extends along the frames 2 and 2, and is spaced in the extending direction. It is supported by a plurality of retainers 24 provided with a gap. That is, the bolt 21, the holding bracket 22, the nut 23, and the retainer 24 are provided at appropriate positions (X portion in FIG. 1) in the extending direction of the mounting bracket 10, but the draining cover 25 extends in a form connecting them. doing.

Next, an attachment procedure will be described.
(1) The 1st metal fitting 11 is fixed to the peak part of the folded-plate roof RF using the sword tip bolt SB.
(2) Cover the first metal fitting 11 with the second metal fitting 12 and fix the side surfaces to each other with screws 16.
(3) The heat insulating material HI is set, and the edge portion is supported on the lower surface portion 15 of the first metal fitting 11.
(4) A heat insulating material presser (spacer) HM is set above the edge of the heat insulating material HI, and the heat insulating material HI is pressed down. Thus, an air layer (wiring space) is secured by the amount of the heat insulating material presser HM.
(5) The solar module 1 is set on the upper surface portion 13 of the second metal fitting 12. Note that a rubber sheet is attached in advance to the upper surface portion 13 of the second metal fitting 12 so as to improve the adhesion with the solar module 1.
(6) The mounting bolt 21 is set in the rail groove 17 (first rail groove 17 a) of the second metal fitting 12, and the holding metal fitting 22 is set on the mounting bolt 21. Then, the mounting bolt 21 and the holding metal fitting 22 are fixed to the fixing bolt 21 along the rail groove 17 (first rail groove 17a), and the holding metal fitting 22 is fixed along the recessed portion 2a of the frame 2. Slide to (X part in FIG. 1).
(7) After setting the retainer 24 on the mounting bolt 21 at each fixing position, the solar module 1 is fixed by the presser fitting 22 by tightening with the nut 23.
(8) The drainage cover 25 is set by being supported by the retainer 24 and fixed with screws.

  According to this embodiment, by setting the heat insulating material HI on the lower surface portion 15 of the second metal fitting 12 and then setting the solar module 1 on the upper surface portion 13, these can be set efficiently, and the workability is improved. Excellent.

  Further, rainwater can enter the space surrounded by the upper surface portion 13 of the second metal fitting 12 and the left and right solar modules 1 and 1 and the frames 2 and 2, but the intruded water enters the rail groove 17 and is discharged according to its inclination. Therefore, further intrusion of water is prevented and sufficient waterproofness can be exhibited.

  Moreover, the 1st metal fitting 11 and the 2nd metal fitting 12 are extended in the inclination direction of the roof, and can ensure the airtightness of the space between the solar module 1 and the heat insulating material HI.

  Further, according to the present embodiment, the rail groove 17 is provided below the first rail groove 17a that forms the bolt engaging portion and the first rail groove 17a, and extends in the same direction so that the draining passage portion is formed. The second rail groove 17b is formed to include the second rail groove 17b, and the second rail groove 17b communicates with the bottom of the first rail groove 17a, thereby dividing the functions of the bolt engaging portion and the draining passage portion, Each can be optimized. In other words, the structure having the second rail groove (drainage passage portion) 17b having a larger cross section independent of the first rail groove (bolt engagement portion) 17a sufficiently enhances the function of discharging the intruded water. Can do.

  Moreover, according to this embodiment, the 1st metal fitting 11 is a lip groove shape steel (C shape steel), and the open side of the groove | channel is arrange | positioned upwards, Therefore A cost increase can be suppressed using a general purpose product. At the same time, the interior can be used as a storage space for the rail groove 17 forming portion of the second metal fitting 12.

  Further, according to the present embodiment, the second metal fitting 12 is fixed to the side surface portion of the first metal fitting 11 at the side surface portion 14, so that the hole processing or the like on the upper surface portion 13 of the second metal fitting 12 is performed. As unnecessary, it is possible to easily ensure waterproofness.

  Further, according to the present embodiment, the height of the side surface portion 14 of the second metal fitting 12 is higher than the thickness of the heat insulating material HI placed on the lower surface portion 15, and between the solar module 1 and the heat insulating material HI. Since the air layer is formed in this way, it is possible to further improve the heat insulation by the air layer and to secure the wiring space.

  Moreover, according to this embodiment, it applies to the roof of a folded plate, and the 1st metal fitting 11 does not need the special process to a roof by setting it as the structure fixed on the mountain-height part of a folded plate, and is general purpose. The solar module 1 can be attached to the folded plate roof, which is a product, in a state having heat insulation and airtightness.

  Moreover, according to this embodiment, in the folded-plate roof, the 1st metal fitting 11 is fixed on the peak part of a folded-plate, and the lower surface part 15 of the 2nd metal fitting 12 mounts the edge part of the heat insulating material HI. Since the height of the bottom surface portion of the first metal fitting 11 (the height of the mountain-height portion) is appropriately related to the height of the lower surface portion 15 of the second metal fitting 12, the heat insulating material HI is Even a flat plate as shown in FIG. 3 can extend above the mountain height without being obstructed by the mountain height of the folded plate. As a result, the heat insulating material HI may be used by cutting a large flat plate-shaped material (general-purpose product) into an appropriate size, and in this respect, the workability is excellent.

  FIG. 5 is a front cross-sectional view showing a manner of attaching the solar module to another folded plate roof (for example, 88 folded plate roof), and FIG.

  As described above, the 66 folded plate roof in FIGS. 3 and 4 has a height h1 of the mountain height of 66 mm and a pitch p1 of the mountain height of 350 mm. When the horizontal size w of the solar module 1 (frame 2) is 984 mm, the mounting bracket 10 is provided on every other mountain height, and the frames 2 and 2 of the solar modules 1 and 1 adjacent in the horizontal direction are fixed. In this case, the interval s1 between the frames 2 and 2 is p1 × 3-w, which is 66 mm. Therefore, when using a tool for attaching the nut 23 to the mounting bolt 21, there is a sufficient margin.

  On the other hand, the 88 folded board roof in FIG.5 and FIG.6 has the height h2 of a mountain height part of 88 mm, and the pitch p2 of a mountain height part is 200 mm. When the horizontal size w of the solar module 1 (frame 2) is 984 mm, the mounting bracket 10 is provided on every fourth mountain height, and the frames 2 and 2 of the solar modules 1 and 1 adjacent in the horizontal direction are fixed. In this case, the interval s2 between the frames 2 and 2 is p2 × 5-w, which is 16 mm. Therefore, there is no allowance, and the tool for tightening the nut 23 cannot be inserted with the mounting structure shown in FIGS.

  Therefore, in the embodiment of FIGS. 5 and 6, the mounting structure is different, which will be described. 5 and 6, the same elements as those in FIGS. 3 and 4 are denoted by the same reference numerals, and different elements will be described.

In the embodiment of FIGS. 5 and 6, the mounting bolt 31 having a length that protrudes from the upper surface height of the solar module 1 is used.
Further, as the presser fitting 32, one having a downward U-shape but a short length in the width direction is used. Since the length is short, reinforcing ribs are not provided, but may be provided as appropriate.

After the presser fitting 32 is set on the mounting bolt 31, the sheath tube 34 is inserted. The sheath tube 34 has a length in which the upper end protrudes slightly from the height of the upper surface of the solar module 1 (frame 2) in the inserted state. And the front-end | tip part of the attachment bolt 31 is taken as the length which protrudes from the upper end part of the sheath pipe 34. As shown in FIG.
A drainage cover 35 is attached to the attachment bolt 31 after the sheath tube 34 is inserted, and is fastened and fixed by a nut 33.

  The drainage cover 35 is a thin plate, is provided so as to straddle the top surfaces of the frames 2 and 2 of the solar modules 1 and 1 adjacent in the lateral direction, extends along the frames 2 and 2, and is spaced in the extending direction. It is supported on a plurality of sheath tubes 34 provided with a gap. That is, the bolt 31, the holding fitting 32, the nut 33, and the sheath tube 34 are provided at appropriate positions (X portion in FIG. 1) in the extending direction of the mounting fitting 10, but the draining cover 35 extends in a form that connects them. Exist.

The attachment procedure in this case is as follows.
(1) to (5) are the same as described above.
(6) The mounting bolt 31 is set in the rail groove 17 (first rail groove 17 a) of the second metal fitting 12, and the holding metal fitting 32 is set on the mounting bolt 31. Then, the fixing bolt 31 and the holding metal fitting 32 are fixed to the fixing bolt 31 along the rail groove 17 (first rail groove 17a), and the holding metal fitting 32 is fixed along the recessed portion 2a of the frame 2. Slide to (X part in FIG. 1).
(7) The sheath tube 34 is set on the mounting bolt 31 at each fixed position. However, the sheath tube 34 may be set before the slide.
(8) The drainage cover 35 is set by being supported by the sheath tube 34, and tightened with the nut 33, so that the solar module 1 is fixed by the presser fitting 32 and at the same time the drainage cover 35 is fixed.

As described above, due to the difference in the roof shape and the like, even if the distance between the frames 2 and 2 on the second metal fitting 12 is different, the same attachment metal fitting 10 (the first metal fitting 11 and the second metal fitting 12) is used. Can respond. That is, it is possible to cope with this by simply preparing a plurality of types of mounting bolts 21 and 31 and presser fittings 22 and 32.
In particular, when the interval is narrow, the workability can be improved by using the sheath tube 34 to make the nut 33 fixed above the solar module 1.

  The illustrated embodiments are merely examples of the present invention, and the present invention is not limited to those directly described by the described embodiments, and various improvements and modifications made by those skilled in the art within the scope of the claims. Needless to say, it encompasses changes.

  For example, in the above description, the solar module is attached to the folded-plate roof. However, the present invention is not limited to this, and the solar module can be attached to a flat roof. In this case, there is no problem because waterproofing can be secured on the second metal fitting 12 even if the first metal fitting 11 is directly attached to the roof to make a hole in the roof.

DESCRIPTION OF SYMBOLS 1 Solar module 1A Solar cell module 1B Heat collection module 2 Frame 2a Recessed part 2b Holding part 3 PV panel 4 Heat collection panel 10 Mounting bracket 11 First bracket 12 Second bracket 13 Upper surface portion 14 Side surface portion 15 Lower surface portion 16 Screw 17 Rail Groove 17a First rail groove (bolt engaging portion)
17b Second rail groove (draining passage)
21 Mounting bolt 22 Holding bracket 23 Nut 24 Retainer 25 Drainage cover 26 Screw 31 Mounting bolt 32 Holding bracket 33 Nut 34 Sheath pipe 35 Drainage cover RF Folded plate roof SB Blade bolt HI Thermal insulation HM Thermal insulation presser (spacer)

Claims (6)

A solar module mounting bracket for fixing a panel-like solar module arranged on the roof,
A first metal fitting fixed on the roof and extending in the roof inclination direction between solar modules adjacent in the lateral direction perpendicular to the roof inclination direction;
A second fitting fixed on the first fitting and extending in the same direction as the first fitting;
Comprising
The second metal fitting includes an upper surface portion located on the first metal fitting, a pair of side surface portions extending downward from the upper surface portion, and a pair of lower surface portions extending outward from the lower ends of the side surface portions. And make a hat-shaped cross section,
The lower surface portion constitutes a placement portion of an edge of a heat insulating material disposed below the solar module,
The upper surface part has a rail groove extending in the extending direction of the second metal fitting at both ends in the width direction at the center part of the width direction as a mounting part of the frame of the solar module.
The rail groove forms a bolt engaging portion that engages a head portion of a mounting bolt with a thread portion facing upward, and forms a draining passage portion that guides water in a tilt direction of the roof,
The solar module mounting bracket, wherein the threaded portion of the mounting bolt forms a mounting portion of a presser bracket that fixes a frame of the solar module. The rail groove includes a first rail groove that forms the bolt engaging portion, a second rail groove that is provided below the first rail groove, extends in the same direction, and forms the draining passage portion. Comprising, and
The solar module mounting bracket according to claim 1, wherein the second rail groove communicates with a bottom portion of the first rail groove.   The solar module mounting bracket according to claim 1 or 2, wherein the first metal fitting is a lip groove steel, and an open side of the groove is arranged upward.   The solar module mounting bracket according to any one of claims 1 to 3, wherein the second bracket is fixed to the side portion of the first bracket at the side portion.   The height of the side surface portion of the second metal fitting is higher than the thickness of the heat insulating material placed on the lower surface portion, and an air layer is formed between the solar module and the heat insulating material. The solar module mounting bracket according to any one of claims 1 to 4, wherein the solar module mounting bracket is characterized. The roof is a folded plate roof,
The solar module mounting bracket according to any one of claims 1 to 5, wherein the first bracket is fixed on a peak portion of the folded plate.